eden - portugal vision 28 05 07
DESCRIPTION
Projecto EDENTRANSCRIPT
Vision for hydrogen development in Portugal until 2050
Introduction
This document gives an overview of a possible hydrogen energy implementation vision1 for
Portugal. Following general considerations on hydrogen energy implementation in Portugal this
document follows a chronological description of how hydrogen energy demand is expected to
develop over time, and how this demand might be met by production (different chains), where
production plants could be located (regional chain distribution), and how infrastructure could
develop. This vision is based on Portuguese stakeholder input and discussions conducted in
connection with PPS6 EDEN workshops.
General considerations on hydrogen energy implementation in Portugal
Stated energy policy goals:
• Improving security of supply
• Promoting economic competition
• Ensuring environmental sustainability
Key energy challenges in Portugal:
• How might the energy security of Portugal be affected by the integration of hydrogen?
Currently Portugal has a high level of oil, coal and natural gas import dependency with
net imports amounting to 86% of TPES.
• Energy is a key challenge for the Portuguese economy. Energy consumption has
experienced four fold growth since 1970, and recently has been non-productive with
demand rising exponentially without corresponding growth in the economy. How can the
integration of hydrogen into this energy system benefit the economy?
• Will the introduction of hydrogen in the energy system bring with it corresponding
reductions in emissions? Portugal targets for carbon emissions under the Kyoto
obligations are forecast to be 13% above the target ceiling (27% increase on 1990 levels)
requiring the use of flexible mechanisms in the carbon markets.
• Portugal has challenging government led targets for RES – 39% of electricity production
by 2010. Will there be RES capacity available to dedicate to hydrogen production or
might hydrogen production and storage together with CHP be used as a load balancing
tool for the grid?
1 Vision is an elaboration of a desirable and (more or less) plausible future. It emphasizes the
benefits of hydrogen.
Likely introduction Feedstock H2 production
CCS 1st
conversion H2 transport
Distribution End use
2020 2030 2050
1 Wind Onsite electrolysis
GH2 filling station / distribution centre
FC transport / stationary
Y
2 Wind Central electrolysis
GH2 truck GH2 filling station / distribution centre
FC transport / stationary
Y
3 Wave power Central electrolysis
Liquefaction LH2 truck LH2 filling station
FC transport Y
4 Solar PV Onsite electrolysis
GH2 filling station / distribution centre
FC transport / stationary
Y
5 Solar heat Thermal conversion
Dedicated pipeline
GH2 filling station / distribution centre
FC transport / stationary
Y
6 Biomass Gasification Liquefaction LH2 truck LH2 filling station / distribution centre
FC transport / stationary
Y
7 Natural gas Onsite SMR GH2 filling station / distribution centre
FC transport / stationary
Y
8 Natural gas Central SMR CCS Dedicated pipeline
GH2 filling station / distribution centre
FC transport / stationary
Y
9 Natural Gas Central SMR CCS GH2 Truck GH2 filling station / distribution centre
FC transport / stationary
Y
10 Coal Gasification CCS Dedicated pipeline
GH2 filling station / distribution centre
FC transport / stationary
Y
11 Coal Gasification CCS GH2 Truck GH2 filling station / distribution centre
FC transport / stationary
Y
12 By-product GH2 truck GH2 filling station
FC transport Y
13 Nuclear Central electrolysis
Dedicated pipeline
GH2 filling station / distribution centre
FC transport / stationary
Y
Table 1 Future hydrogen chains
Vision of future hydrogen chains
Below are reflections on the possible use of chains in table 1 within the timeframe under
consideration by the EDEN project.
a. Entry phase (until 2020)
The entry phase is characterised by low demand for hydrogen. The emerging market for
hydrogen will be particularly found in the portable applications and the transportation sector
(captive fleets, public transport…). In the entry phase, the early markets would require small
quantities of hydrogen produced by steam methane reforming (SMR) (chain 7), or by-product
(chain 12), or onsite via electrolysis using energy from the electricity grid (chain 16). The
production of hydrogen via onsite and central electrolysis using electricity from wind parks (chains
1 & 2) as well as via biomass gasification (chain 6) also represent options for hydrogen
production in this early phase. The hydrogen will be transported using the existing infrastructures
(GH2 or LH2 trucks) and distributed via bespoke demonstration projects and early fleet
integration.
b. Transition phase (2020 - 2030)
In the transition phase the growth of hydrogen demand enlarges the range of options for local and
central hydrogen production, as a result more efficient and larger scale forms of production must
be developed. New options include central electrolysis via wave (chain 3), and expanding central
electrolysis capacity for wind (chain 2) as well as expanding biomass gasification (chain 6)
alongside on-site electrolysis based on wind energy and solar PV (chains 1 & 4). The capture and
storage of CO2 from central SMR installations (chain 8) and coal gasification plants (chain 11) is
envisaged later in this time period. It is also envisaged that there will be potential for producing
hydrogen centrally with electricity from the grid during this second phase (chain 14). The use of
GH2 and LH2 trucks and some early dedicated infrastructures (such as dedicated hydrogen
pipelines). Initial distribution centres are small in scale and located close to areas of high
14 El Grid Central electrolysis
Dedicated pipeline
GH2 filling station / distribution centre
FC transport / stationary
Y
15 El Grid Onsite electrolysis
GH2 filling station / distribution centre
FC transport / stationary
Y
16 Import H2 Ship GH2 filling station / distribution centre
FC transport / stationary
Y
demand, such as major urban centres. Transport and stationary applications for hydrogen are
projected to begin to reach the market during this time.
c. Long term phase (2030 - 2050 and onwards)
Massive production of hydrogen is envisaged over the long term. This makes it necessary to take
into consideration the CO2-free and high yield mass production of hydrogen from the
development of nuclear high temperature reactors, based on electrolysis (chain 13). Also taken
into account is the production from the thermal conversion of solar heat (chain 5). The import of
hydrogen via ship (chain 16) may become economic in this phase from a diverse range of
countries rich in natural energy such as Iceland (geothermal), or Norway (natural gas) or even
some African countries should solar thermal take off. The transport of hydrogen by dedicated
pipeline becomes progressively the most attractive option for significant quantities of hydrogen
whereas transport by truck is preferred for smaller quantities. The distribution of the hydrogen is
delivered to the consumers via refuelling stations, for hydrogen cars, and distribution centres,
through local hydrogen pipelines, for the heating and cooling needs of individual households,
buildings and industry. The refuelling stations are sited near urban centres and along main roads
and the distribution centres near urban and industrial areas.